KOREAN JOURNAL OF CROP SCIENCE (한국작물학회지)

The Korean Society of Crop Science (한국작물학회)
권호 표지

N Top-Dressing and Rice Straw Application for Low-Input Cultivation of Transplanted Rice in Japan

  • Cho, Y.S. (Dept. of Agriculture, Faculty of Life and Environmental Science, Shimane University) ;
  • Kobata, T. (Dept. of Agriculture, Faculty of Life and Environmental Science, Shimane University)
  • Published : 2002.09.01
Download PDF
⟨ Previous Next ⟩

Abstract

An efficient low-input system (LIS) for fertiliser use in rice cultivation is necessary to reduce fossil energy use and pollution. Japanese people like Japonica rice, especially cv. Koshihikari. However, it has very low lodging resistance in Japanese weather condition. Our objective was to develop a LIS with the minimum sacrifice of grain yield in rice. Koshihikari was grown using conventional fertilization as a control (CON) with 4 g N $m^{-2}$., 8g $P_2$ $O_{5}$ $m^{-2}$ and 8 g $K_2$O $m^{-2}$ as a basal fertilizer dressing. It was compared with a low fertilizer treatment (LF) with only 4 g $P_2$ $O_{5}$ $m^{-2}$ as a basal dressing in the first year and no basal phosphorus fertilizer in the second year. Chopped rice straw was incorporated into the soil before the cropping season in both years. Fertilizer of 4 g N $m^{-2}$ was top-dressed at 15 days before heading in CON plots and 30 days before heading in LF plots in both years. Lodging was significantly less in LF than in CON plots, however, no rice straw effect was found in low fertilized condition. Grain yields in LF plots were reduced by 15-16% below those of CON plots. Lower yields in LF plots were associated with a reduced number of spikelets per unit area. However, big spikelet size was acquired in LF by 10 days earlier N top dressing than CON plots. A close relationship was found between spikelet numbers and N content of the plant at heading, and between grain yield or shoot dry weight and N content of the plant at maturity. Regardless of the fertilizer application methods, N use efficiency for the number of spikelets, final total dry matter and grain yield was essentially identical among fertilizer treatments. The reduced growth and yield in the LF plots resulted from low absorption of nitrogen. Conclusively, LIS can drastically reduce chemical fertilizer use and facilitate harvest operations by reducing lodging with some yield reduction..

Keywords

References

  1. Cassman K. G, G. C. Gines, M. A. Dizon, M. Samson, J. M. Alcantara. 1996. Nitrogen use efficiency in tropical lowland rice systems. Contributions from indigenous and applied nitrogen. Fietd Crops Res. 47 : 1-12 https://doi.org/10.1016/0378-4290(95)00101-8
  2. Cho Y. S, Z.R. Choe, S. E. Ockerby. 2001. Managing tillage, sow-ing rate and nitrogen top-dressing level to sustain nce yield in a low-input, direct-sown, vetch-rice cropping system. Australian Journal of Experimental Agriculture. 41. 1. 61-69 https://doi.org/10.1071/EA00075
  3. Cho Y. S, B. Z. Lee, and Z. R. Choe. 1999. Nitrogen mineraliza tion of cereal straws and vetch in paddy soil by test tube analy sis. Korean J. Crop Sci. 44(2): 102-105
  4. Dei Y. 1970. Application of rice straw to paddy fields. JARQ 5: 5-8
  5. Dingkuhn M. H. F. Schnier, S. K. De Datta, K. Dorffling, C. Javellana, R. Pamplona. 1990. Nitrogen fertilization of direct-seeded flooded vs. transplanted rice: II. Interactions among canopy properties. Crop Sci. 30 : 1284-1292 https://doi.org/10.2135/cropsci1990.0011183X003000060025x
  6. Evans L.T. 1993. Crop evolution, adaptation and yield. Cambridge University Press, Cambndge, 1-500
  7. Goulding K. W. T., N. J. Bailey, N. J. Bradbury, P. Hargreaves, M. Howe, D. V. Murphy, P. R. Poulton, and T. W. Willison. 1998. Nitrogen deposition and its contribution to nitrogen cycling and associated soil processes. New Physiol. 139 : 49-58 https://doi.org/10.1046/j.1469-8137.1998.00182.x
  8. Hara Y, K. Toriyama. 1997. Effect of the nitrogen application and planting density on the growth and yield of a rice variety 'Dongtokoi'. Annuat report in Hokuriku National Agricuttural Experiment Station. 40 : 79-85
  9. Hashikawa U. 1996. A Proposal for 21 Century : Realizable for Low Input System in Rice Cultivation. Fumin Kyokai, Tokyo. 1-366
  10. Ishihara K. E., H. Bara, T. Hirasawa, T. Ogura. 1978. The reladon-ship between environmental factors and behavior of stomata in the rice plants. VII. The relation between nitrogen content in leaf blades and stomatal aperture. Jpn. J. Crop Sci. 47 : 664-673 https://doi.org/10.1626/jcs.47.664
  11. Keeney D. R. 1982. Nitrogen management for maximum effi-ciency and minimum pollution in nitrogen in agricultural soils. Stevenson, F.J. ed. Amehcan society of agronomy. Madison, WZ, 1-605
  12. Loomis R. S., D. J. Connor. 1992. Crop Ecology, Physiology, Producdvity and Management of Agricultural System. Cambridge University Press, 1-538
  13. Murayama N. (1982) The Conquest of the Law of Diminishing Retums in Crop Production. Yokendo Co. Tokyo. 50-54
  14. Rao D.N., D.S. Mikkelsen. 1976. Effect of rice straw incorporation on rice growth and nuthtion. Agron. J. 68 : 752-755 https://doi.org/10.2134/agronj1976.00021962006800050017x
  15. Shqji S, H. Ando, G. Wada. 1986. Fate of nitrogen in paddy fields and nitrogen absorption by rice plants. JARQ., 20 : 127-133Watanabe T, Y. Nishikawa, K. Wada, A. Fujishiro, Y. Ebata. 1988. Lodging protection in paddy rice. Agr. & Hort. 67 : 507-514 (in Japanese)
  16. Williams W. A., D.S. Mikkelsen, K. E. Mueller, J. E. Ruckman. 1968. Nitrogen immobilization by rice straw incorporated in lowland rice production. Plant Soil 28 : 49-60 https://doi.org/10.1007/BF01349177
  17. Yoon U. S. 1998. Long-term vahability of nitrogen use efficiency and yield in paddy rice. Ph.D. Thesis. Gyeongsang Nat'l Univ. 10-33
  18. York E. T. 1994. Global prospectives on intemational agricultural research. In Physiology and Determination of Crop Yield. Ed. K. J. Boote, J. M. Bennet, T. R. Sinclair and G. M. Paulsen. ASA, CSSA and SSSA, Madison, 1-17
  19. Yoshida S, V. Coronel. 1976. Nitrogen nutrition, leaf resistance, and leaf photosynthetic rate of the rice plant. Soil Sci. Plant Nutr. 22: 207-211 https://doi.org/10.1080/00380768.1976.10432983